In vitro biliary excretion assay

ABSTRACT

An in vitro methods of characterizing biliary excretion of a chemical entity using a single hepatocyte culture. Comprising providing cell culture comprising hepatocytes forming at least one bile canaliculus; contacting the cell culture with a first chemical entity for a time sufficient to allow uptake of the chemical entity by hepatocytes in the culture; disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and lysing the hepatocytes and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes.

INTRODUCTION

Therapeutic chemical entities are often undesirably removed from an animal's circulatory system by first-pass metabolism in the liver. If a chemical entity is taken up by hepatocytes and excreted in bile via the bile canaliculi the chemical entity will never reach its therapeutic target. Transport proteins endogenous to hepatocytes are responsible for moving substrates across the sinusoidal membrane of the hepatocytes and then into bile canaliculi. Bile canaliculi are structures within liver tissue that receive excreted components from the hepatocytes and transport the bile to a common bile duct for removal from the animal. Biliary excretion of substrates is thus a complex process involving translocation across the sinusoidal membrane, movement through the cytoplasm, and transport across the canalicular membrane.

Understanding that hepatobiliary excretion of parent drugs or their metabolites often play a significant role in the overall clearance of a drug has forced the pharmaceutical industry to explore better in-vitro tools for predicting this avenue of clearance. For this reason an important determinate of the suitability of a chemical entity for use as a pharmaceutical is both the degree to which it is subject to biliary excretion and the effect it has on biliary excretion of other chemical entities.

The art has taught two general types of in vitro assays for biliary clearance of a chemical entity. The first assay type is a two-culture assay format that utilizes two parallel cultures of hepatocytes. (B I, Yi-an, et al., “Use of cryopreserved human hepatocytes in sandwich culture to measure hepatobiliary transport,” Drug Metab Dispos., Vol. 34, No. 9, pp. 1658-65 (2006); ANSEDE, John H., et al., “An In Vitro Assay to Assess Transporter-Based Cholestatic Hepatotoxicity Using Sandwich-Cultured Rat Hepatocytes,” Drug metabolism and Disposition, Vol. 38, pp. 276-280 (2010).) In the first culture hepatocytes are exposed to normal culture media and form and maintain canaliculi. In the second culture hepatocytes are exposed to culture media designed to disrupt canaliculi, such as culture media that is calcium and magnesium free. A chemical entity is then exposed to each culture and allowed to interact with the hepatocytes for a culture period. Then the cultures are washed and the amount of chemical entity associated with the cells in each culture is assessed. In the first culture chemical entity associated with the cells may be localized in the cell cytoplasm or present in canaliculi following biliary excretion. In the second culture there are no intact canaliculi so any chemical entity associated with the cells must be present in the cytoplasm. By suntracting the amount of chemical entity present in the cytoplasm (second culture) from the amount of chemical entity present in the cytoplasm and the canaliculi (first culture) it is possible to determine the amount of chemical entity excreted in the bile of the first cell culture.

The two-culture assay format has several drawbacks. A first drawback is the simple reality that creating a single biliary excretion data point using this assay format requires two cultures of primary hepatocytes. Primary hepatocytes are difficult to procure and therefore are very expensive. Thus, there is a need in the art for methods of characterizing biliary excretion of chemical entities using fewer primary hepatocytes. Clearly, a one culture method will achieve a 50% reduction in the number of primary hepatocytes needed for the assay and is, therefore, very desirable. A second drawback is that biliary accumulation of a chemical entity is necessarily calculated in a two-culture assay format by measuring two values that are not biliary accumulation, namely total cellular accumulation (cytoplasm and bile) and cytoplasmic accumulation, and then calculating the difference between these values. A measurement made utilizing this two-culture process will necessarily have more inherent variability than a single, direct measurement of biliary accumulation. A direct measurement of biliary accumulation is not possible in the two-culture assay format.

The art has also taught a single-culture in vitro assays for biliary clearance of a chemical entity. (U.S. Pat. No. 7,604,934.) However, the previously taught assay is indirect. Specifically, it relies on exposing a single culture to a marker compound (such as a radiolabeled compound) and comparing biliary accumulation of the radioactive marker in the presence and absence of a test chemical entity. Such assays assume that a drop in biliary accumulation of the marker in the presence of the test chemical entity indicates that the test chemical entity is excreted by a pathway similar to that used by the marker compound. This assay format has several drawbacks including low accuracy.

For all of the above reasons and others there is a need in the art for new and efficient methods of assessing the biliary excretion of chemical entities such as candidate therapeutic agents. This invention provides new and nonobvious methods that meet these and other needs.

SUMMARY

This invention provides new and improved in vitro methods of characterizing biliary excretion of a chemical entity. In a first aspect, the methods comprise a) providing cell culture comprising hepatocytes forming at least one bile canaliculus; b) contacting the cell culture with a first chemical entity for a time sufficient to allow uptake of the chemical entity by hepatocytes in the culture; c) disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and d) lysing the hepatocytes and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes. In some embodiments at least one wash step is included between steps a) and b), between steps b) and c), and/or between steps c) and d).

One feature of the disclosed methods is that biliary accumulation of a chemical entity and cytoplasmic accumulation of the chemical entity are both measured using a single hepatocyte culture, such as a single well of the tissue culture plate. Surprisingly, and as discussed below and demonstrated in the examples, this assay format is highly accurate and reproducible.

In some embodiments of the methods the cell culture is a hepatocyte-stromal cell coculture comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c) is higher than the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes in step d).

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c) is lower than the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes in step d).

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof in steps c) and/or d) is detected using LC-MS/MS.

In some embodiments of the methods the first chemical entity does not comprise a label.

In some embodiments of the methods the at least one bile canaliculus is disrupted without lysing hepatocytes in the culture by incubating the culture in media comprising latrunculin A (LatA) and/or not comprising calcium.

In some embodiments the methods further comprise determining the intrinsic biliary clearance (CL_(bile)) and/or the biliary excretion index (BEI) for the first chemical entity in the cell culture.

In some embodiments the methods further comprise determining the intrinsic biliary clearance (CL_(bile)) and/or the biliary excretion index (BEI) for the first chemical entity in the cell culture; and further comprise comparing the CL_(bile) and/or BEI of the first chemical entity to the CL_(bile) and/or BEI of a control chemical entity and characterizing the biliary excretion of the first chemical entity based on the comparison.

In some embodiments of the methods the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes.

In some embodiments the methods further comprise contacting the cell culture with a second chemical entity in step b).

In some embodiments the methods further comprise contacting the cell culture with a second chemical entity in step b); and the methods, further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c).

In some embodiments the methods further comprise contacting the cell culture with a second chemical entity in step b); and the methods, further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c); and the methods further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the hepatocytes in step d).

In a second aspect, the methods comprise a) providing a first cell culture comprising hepatocytes forming at least one bile canaliculus, wherein the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes of the first cell culture; b) contacting the first cell culture with a first chemical entity; c) disrupting the at least one bile canaliculus in the first cell culture without lysing the hepatocytes in the first cell culture and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; d) lysing the hepatocytes in the first cell culture and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes; e) providing a second cell culture comprising hepatocytes forming at least one bile canaliculus, wherein the activity of the at least one hepatocyte transport protein is not inhibited in the hepatocytes of the second cell culture; f) contacting the second cell culture with the first chemical entity; g) disrupting the at least one bile canaliculus in the second cell culture without lysing the hepatocytes in the second cell culture and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and h) lysing the hepatocytes in the second cell culture and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes. In some embodiments at least one wash step is included between steps a) and b), between steps b) and c), and/or between steps c) and d). In some embodiments at least one wash step is included between steps e) and f), between steps f) and g), and/or between steps g) and h).

In some embodiments of the methods the first and second cell cultures are hepatocyte-stromal cell cocultures comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture; and the CL_(bile) and/or BEI for the first chemical entity is lower in the first cell culture than in the second cell culture, indicating that biliary clearance of the first chemical entity is mediated at least on part by the at least one hepatocyte transport protein.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture; and the CL_(bile) and/or BEI for the first chemical entity is not lower in the first cell culture than in the second cell culture, indicating that biliary clearance of the first chemical entity is not mediated at least on part by the at least one hepatocyte transport protein.

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof in steps c) and/or d) and/or e) and/or h) is detected using LC-MS/MS.

In some embodiments of the methods the first chemical entity and/or a metabolite thereof in steps b) and/or f) does not comprise a label.

In some embodiments of the methods the at least one bile canaliculus is disrupted in the first and second cell cultures without lysing hepatocytes in the cell cultures by incubating the cell cultures in media comprising latrunculin A (LatA) and/or not comprising calcium.

In some embodiments the methods further comprise contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f).

In some embodiments the methods further comprise contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f); and further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in steps c) and/or g).

In some embodiments the methods further comprise contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f); and further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in steps c) and/or g); and further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the hepatocytes in steps d) and/or h).

In a third aspect, the methods comprise a) providing a cell culture comprising hepatocytes forming at least one bile canaliculus; b) simultaneously contacting the cell culture with a marker chemical entity and a test chemical entity, wherein the marker chemical entity is a known substrate of at least one hepatocyte transport protein with a determined CL_(bile) and/or BEI; c) disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount of the marker chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and d) lysing the hepatocytes and detecting the amount of the marker chemical entity and/or a metabolite thereof released by the hepatocytes. In some embodiments at least one wash step is included between steps a) and b), between steps b) and c), and/or between steps c) and d).

In some embodiments of the methods the cell culture is a hepatocyte-stromal cell coculture comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity; and the CL_(bile) and/or BEI for the marker chemical entity is lower in the presence of the test chemical entity than in the absence of the test chemical entity, indicating that biliary clearance of the test chemical entity is mediated at least in part by the at least one least one hepatocyte transport protein.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity; and the CL_(bile) and/or BEI for the marker chemical entity is not lower in the presence of the test chemical entity than in the absence of the test chemical entity, indicating that biliary clearance of the test chemical entity is not mediated at least in part by the at least one least one hepatocyte transport protein.

In some embodiments of the methods the amount of the marker chemical entity and/or metabolite thereof in steps c) and/or d) is detected using LC-MS/MS.

In some embodiments of the methods the at least one bile canaliculus is disrupted in the cell culture without lysing hepatocytes in the cell culture by incubating the cell culture in media comprising latrunculin A (LatA) and/or not comprising calcium.

In some embodiments of the methods the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes of the cell culture.

BRIEF DESCRIPTION OF THE DRAWINGS

FIG. 1 shows accumulation of taurocholate in the bile. The graph shows the concentration of taurocholate obtained from the collection 4 sample which contains only substrate secreted into the bile. The bars represent samples that were obtained by disrupting the canaliculus with Ca− buffer or LatA buffer. All concentrations were determined using LC-MS/MS.

FIG. 2 shows accumulation of taurocholate in the cell. The graphs show the concentration of taurocholate obtained from the collection 5 sample which contains only substrate accumulated in the cell. The bars represent samples that were obtained after disrupting the canaliculus with Ca− buffer or LatA buffer in collection 4. All concentrations were determined using LC-MS/MS.

FIG. 3 shows accumulation of taurocholate in the bile after inhibition with CSA. The graphs show the concentration of taurocholate obtained from the collection 4 sample which contains only substrate accumulated in the bile after incubation with transporter inhibitor CSA. The bars represent samples that were obtained after disrupting the canaliculus with Ca− buffer or LatA buffer or incubation with CSA and disruption with Ca− buffer in collection 4. All concentrations were determined using LC-MS/MS.

FIG. 4 shows biliary uptake of taurocholate by primary human hepatocytes grown in a hepatocyte-stromal cell coculture. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 67% for taurocholate.

FIG. 5 shows biliary uptake of estradiol-glucuronide by cultured human hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 40% for estradiol-glucuronide.

FIG. 6 shows biliary uptake of digoxin by cultured human hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 41% for digoxin.

FIG. 7 shows biliary uptake of rosuvastatin by cultured human hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 52% for rosuvastatin.

FIG. 8 shows biliary uptake of pravastatin by cultured human hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 14% for pravastatin.

FIG. 9 shows biliary uptake of taurocholate by cultured rat hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 60% for taurocholate.

FIG. 10 shows biliary uptake of rosuvastatin by cultured rat hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 72% for rosuvastatin.

FIG. 11 shows biliary uptake of estradiol-glucuronide by cultured rat hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 45% for estradiol-glucuronide.

FIG. 12 shows biliary uptake of digoxin by cultured rat hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 67% for digoxin.

FIG. 13 shows biliary uptake of pravastatin by cultured rat hepatocytes. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of the bar on the left side of the graph and compared to the measured bile accumulation shown in the bar on the right side of the graph. The measured values were used to calculate a BEI of 58% for pravastatin.

FIG. 14 shows inhibition by cyclosporin A of BSEP-mediated transport of taurocholate. The data indicate an IC₅₀ value of 0.46 mM in this system.

FIG. 15 shows shows inhibition by ritonavir of BCRP-mediated transport of rosuvastatin. The data indicate an IC₅₀ value of 0.50 mM in this system.

FIG. 16 shows inhibition by erythromycin-estolate of BSEP-mediated transport of taurocholate and BCRP-mediated transport of rosuvastatin. BSEP was completely inhibited in this experiment.

FIG. 17 compares the results of three independent experiments measuring biliary uptake of taurocholate by primary human hepatocytes grown in a hepatocyte-stromal cell coculture. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of a single bar. The error bars represent a single standard deviation. Analysis of every pairwise combination of the experiments indicated that the variation in the results is not statistically significant.

FIG. 18 compares the results of three independent experiments measuring biliary uptake of pravastatin by primary human hepatocytes grown in a hepatocyte-stromal cell coculture. Accumulation in the bile and accumulation in the cell were measured separately in a single well of a coculture plate. The measured values for bile accumulation and cell accumulation are shown as separately shaded portions of a single bar. The error bars represent a single standard deviation. Analysis of every pairwise combination of the experiments indicated that the variation in the results is not statistically significant.

DETAILED DESCRIPTION

The in vitro methods of this invention utilize cultured hepatocytes that have formed at least one biliary canaliculus. A feature of the methods is that two different direct measurements are obtained from a single culture of hepatocytes in the methods of the invention. First, the amount of a chemical entity excreted into the biliary canaliculi of the culture is measured directly. Then, the amount of the chemical entity that is imported into the hepatocyte cytoplasm but not excreted into the biliary canaliculi is measured directly. The features of direct measurement and use of a single culture for both measurements distinguish the methods of the invention from prior art methods and provide several advantages that will be apparent to a skilled artisan in view of this disclosure.

A. Single Culture Biliary Excretion Assay

In certain embodiments the methods of this invention comprise a) providing a cell culture comprising hepatocytes forming at least one bile canaliculus; b) contacting the cell culture with a first chemical entity for a time sufficient to allow uptake of the chemical entity by hepatocytes in the culture; c) disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and d) lysing the hepatocytes and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes. In some embodiments of the methods at least one wash step is included between steps a) and b), between steps b) and c), and/or between steps c) and d).

Typically step b) is performed by diluting a first chemical entity in culture media and replacing the culture media used in step a) with the media comprising the diluted first chemical entity. After a time sufficient to allow uptake the culture media of step b) is removed from the culture. Because the hepatocytes are typically adhered to a substrate this is typically accomplished using standard tissue culture aspiration and pipetting techniques or equivalent to remove culture media and then add new media Of course, a skilled artisan will appreciate that any suitable method may be used. At this stage of the method the hepatocyte culture may be washed by one or more changes of culture media that does not comprise the first chemical entity, such as by one wash, by two washes, or by three washes.

In some embodiments, following step b) the cell culture comprising hepatocytes forming at least one bile canaliculus is incubated in fresh media for a culture period and the culture media is then collected. This culture media may be analyzed for accumulation of first chemical entity in the culture media. First chemical entity that accumulates under this culture conditions will have originated form basolateral transport processes of the hepatocytes and thus inclusion of this step in embodiments of the methods allows measurement of basolateral transport, biliary accumulation, and cytoplasmic accumulation of a chemical entity in a single cell culture comprising hepatocytes forming at least one bile canaliculus.

In step c) the at least one bile canaliculus is disrupted by any suitable technique known in the art. An exemplary method is by exchanging the culture media with media that is calcium free or that is calcium and magnesium free. Incubation in media that is calcium free or that is calcium and magnesium free disrupts tight junctions and causes the contents of bile canaliculi to be released into the culture media. Another exemplary method is by exchanging the culture media for media comprising an effective concentration of LatA, Incubation in media that comprising an effective concentration of LatA disrupts tight junctions and causes the contents of bile canaliculi to be released into the culture media. The detecting in step c) typically is by collecting the media following disruption of canaliculi and characterization of first chemical entity present in the collected media. The detection may be qualitative and/or quantitative. In a preferred embodiment the detection methods comprise use of LC-MS/MS to detect the first chemical entity. In some embodiments LC-MS/MS is used to measure the amount of the first chemical entity present in the media following disruption of the at least one bile canaliculus. In some embodiments the media comprising the material released from the canaliculi is processed to remove undesirable components using steps that may include, for example, at least one of filtration, chromatography, centrifugation, and evaporation.

In step d) the remaining cells are lysed by any suitable technique known in the art. An exemplary method is by exposure to deionized water. The detecting in step d) typically is by collecting the media following lysing of the remaining cells and characterization of first chemical entity present in the collected media. The detection may be qualitative and/or quantitative. In a preferred embodiment the detection methods comprise use of LC-MS/MS to detect the first chemical entity. In some embodiments LC-MS/MS is used to measure the amount of the first chemical entity present in the media following cell lysis. In some embodiments the media comprising the material released from the lysed cells is processed to remove undesirable components using steps that may include, for example, at least one of filtration, chromatography, centrifugation, and evaporation.

The cell culture comprising hepatocytes forming at least one bile canaliculus may be any suitable hepatocyte culture. Typically the cell culture comprising hepatocytes forming at least one bile canaliculus is a culture configuration that does not comprise a liver slice. Exemplary cell cultures comprising hepatocytes forming at least one bile canaliculus are described in Section D: “Cultures Comprising Hepatocytes Forming a Bile Canaliculus” of this DETAILED DESCRIPTION section of the disclosure. Any Cultures Comprising Hepatocytes Forming a Bile Canaliculus may be used in the methods of this disclosure.

In some embodiments of the methods the cell culture is a hepatocyte-stromal cell coculture comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c) is higher than the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes in step d).

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c) is lower than the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes in step d).

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof in steps c) and/or d) is detected using LC-MS/MS. In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof in steps c) and d) is detected using an equivalent LC-MS/MS technique.

In some embodiments of the methods the first chemical entity does not comprise a label. As used herein a “label” is a moiety that emits a signal that may be detected in an assay. Exemplary labels are fluorescent moieties and radioactive moieties.

In some embodiments the methods do not comprise detecting a signal from a label moiety of a chemical entity.

In some embodiments of the methods the at least one bile canaliculus is disrupted without lysing hepatocytes in the culture by incubating the culture in media comprising latrunculin A (LatA) and/or not comprising calcium.

In some embodiments the methods further comprise determining the intrinsic biliary clearance (CL_(bile)) and/or the biliary excretion index (BEI) for the first chemical entity in the cell culture.

In some embodiments the methods further comprise determining the intrinsic biliary clearance (CL_(bile)) and/or the biliary excretion index (BEI) for the first chemical entity in the cell culture; and further comprise comparing the CL_(bile) and/or BEI of the first chemical entity to the CL_(bile) and/or BEI of a control chemical entity and characterizing the biliary excretion of the first chemical entity based on the comparison.

In some embodiments of the methods the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes. In some embodiments the at least one hepatocyte transport protein is selected from at least one sinusoidal membrane transport protein and at least one bile membrane transport protein. In some embodiments the at least one hepatocyte transport protein is selected from NTCP, OATP1A1, OATP1A2, OATP1A4, OATPB2, OATP1B1, OATP1B3, OATP2B1, OAT2, OAT3, OAT4, OCT1, OCT3, OCTN1, OCTN2, BSEP, MRP1, MRP2, MRP3, MRP4, MRP5, MRP6, MRP7, MRP8, MRP9, MDR1, MDR1A/B, MDR2, MDR3, BCRP, ABCG5, ABCG8, and FIC-1.

In some embodiments the methods further comprise contacting the cell culture with a second chemical entity in step b).

In some embodiments the methods further comprise contacting the cell culture with a second chemical entity in step b); and the methods, further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c).

In some embodiments the methods further comprise contacting the cell culture with a second chemical entity in step b); and the methods, further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c); and the methods further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the hepatocytes in step d).

B. Single Culture Biliary Excretion Assay with Hepatocyte Transporter Inhibition

In certain embodiments the methods of this invention comprise comparing (1) biliary excretion of a first chemical entity in cultured hepatocytes in which the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes with (2) biliary excretion of the first chemical entity in cultured hepatocytes in which the activity of at least one hepatocyte transport protein is not inhibited in the hepatocytes, in order to characterize the effect of inhibition of the at least one hepatocyte transport protein on biliary excretion of the first chemical entity. For example, such methods may comprise a) providing a first cell culture comprising hepatocytes forming at least one bile canaliculus, wherein the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes of the first cell culture; b) contacting the first cell culture with a first chemical entity; c) disrupting the at least one bile canaliculus in the first cell culture without lysing the hepatocytes in the first cell culture and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; d) lysing the hepatocytes in the first cell culture and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes; e) providing a second cell culture comprising hepatocytes forming at least one bile canaliculus, wherein the activity of the at least one hepatocyte transport protein is not inhibited in the hepatocytes of the second cell culture; f) contacting the second cell culture with the first chemical entity; g) disrupting the at least one bile canaliculus in the second cell culture without lysing the hepatocytes in the second cell culture and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and h) lysing the hepatocytes in the second cell culture and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes. In some embodiments at least one wash step is included between steps a) and b), between steps b) and c), and/or between steps c) and d). In some embodiments at least one wash step is included between steps e) and f), between steps f) and g), and/or between steps g) and h).

Typically steps b) and f) are performed by diluting a first chemical entity in culture media and replacing the culture media used in steps a) or e) with the media comprising the diluted first chemical entity. After a time sufficient to allow uptake the culture media of step b) or f) is removed from the culture. Because the hepatocytes are typically adhered to a substrate this is typically accomplished using standard tissue culture aspiration and pipetting techniques or equivalent to remove culture media and then add new media Of course, a skilled artisan will appreciate that any suitable method may be used. At this stage of the method the hepatocyte culture may be washed by one or more changes of culture media that does not comprise the first chemical entity, such as by one wash, by two washes, or by three washes.

In some embodiments, following steps b) and/or f) the cell culture comprising hepatocytes forming at least one bile canaliculus is incubated in fresh media for a culture period and the culture media is then collected. This culture media may be analyzed for accumulation of first chemical entity in the culture media. First chemical entity that accumulates under this culture conditions will have originated form basolateral transport processes of the hepatocytes and thus inclusion of this step in embodiments of the methods allows measurement of basolateral transport, biliary accumulation, and cytoplasmic accumulation of a chemical entity in a single cell culture comprising hepatocytes forming at least one bile canaliculus.

In steps c) and f) the at least one bile canaliculus is disrupted by any suitable technique known in the art. An exemplary method is by exchanging the culture media with media that is calcium free or that is calcium and magnesium free. Incubation in media that is calcium free or that is calcium and magnesium free disrupts tight junctions and causes the contents of bile canaliculi to be released into the culture media. Another exemplary method is by exchanging the culture media for media comprising an effective concentration of LatA, Incubation in media that comprising an effective concentration of LatA disrupts tight junctions and causes the contents of bile canaliculi to be released into the culture media. The detecting in steps c) and f) typically is by collecting the media following disruption of canaliculi and characterization of first chemical entity present in the collected media. The detection may be qualitative and/or quantitative. In a preferred embodiment the detection methods comprise use of LC-MS/MS to detect the first chemical entity. In some embodiments LC-MS/MS is used to measure the amount of the first chemical entity present in the media following disruption of the at least one bile canaliculus. In some embodiments the media comprising the material released from the canaliculi is processed to remove undesirable components using steps that may include, for example, at least one of filtration, chromatography, and centrifugation.

In steps d) and h) the remaining cells are lysed by any suitable technique known in the art. An exemplary method is by exposure to deionized water. The detecting in steps d) and h) typically is by collecting the media following lysing of the remaining cells and characterization of first chemical entity present in the collected media. The detection may be qualitative and/or quantitative. In a preferred embodiment the detection methods comprise use of LC-MS/MS to detect the first chemical entity. In some embodiments LC-MS/MS is used to measure the amount of the first chemical entity present in the media following cell lysis. In some embodiments the media comprising the material released from the lysed cells is processed to remove undesirable components using steps that may include, for example, at least one of filtration, chromatography, and centrifugation.

The cell cultures comprising hepatocytes forming at least one bile canaliculus may be any suitable hepatocyte culture. Typically the cell cultures comprising hepatocytes forming at least one bile canaliculus are cultures in a configuration that does not comprise a liver slice. Exemplary cell cultures comprising hepatocytes forming at least one bile canaliculus are described in Section D: “Cultures Comprising Hepatocytes Forming a Bile Canaliculus” of this DETAILED DESCRIPTION section of the disclosure. Any Cultures Comprising Hepatocytes Forming a Bile Canaliculus may be used in the methods of this disclosure.

In some embodiments of the methods the first and second cell cultures are hepatocyte-stromal cell cocultures comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture; and the CL_(bile) and/or BEI for the first chemical entity is lower in the first cell culture than in the second cell culture, indicating that biliary clearance of the first chemical entity is mediated at least on part by the at least one hepatocyte transport protein.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture; and the CL_(bile) and/or BEI for the first chemical entity is not lower in the first cell culture than in the second cell culture, indicating that biliary clearance of the first chemical entity is not mediated at least on part by the at least one hepatocyte transport protein.

In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof in steps c) and/or d) and/or e) and/or h) is detected using LC-MS/MS. In some embodiments of the methods the amount of the first chemical entity and/or a metabolite thereof in steps c) and d) and g) and h) is detected using an equivalent LC-MS/MS technique.

In some embodiments of the methods the first chemical entity and/or a metabolite thereof in steps b) and/or f) does not comprise a label. As used herein a “label” is a moiety that emits a signal that may be detected in an assay. Exemplary labels are fluorescent moieties and radioactive moieties.

In some embodiments the methods do not comprise detecting a signal from a label moiety of a chemical entity.

In some embodiments of the methods the at least one bile canaliculus is disrupted in the first and second cell cultures without lysing hepatocytes in the cell cultures by incubating the cell cultures in media comprising latrunculin A (LatA) and/or not comprising calcium.

In some embodiments the methods further comprise contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f).

In some embodiments the methods further comprise contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f); and further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in steps c) and/or g).

In some embodiments the methods further comprise contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f); and further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in steps c) and/or g); and further comprise detecting the amount of the second chemical entity and/or a metabolite thereof released by the hepatocytes in steps d) and/or h.

In some embodiments of the methods the at least one hepatocyte transport protein is selected from at least one sinusoidal membrane transport protein and at least one bile membrane transport protein. In some embodiments the at least one hepatocyte transport protein is selected from NTCP, OATP1A1, OATP1A2, OATP1A4, OATPB2, OATP1B1, OATP1B3, OATP2B1, OAT2, OAT3, OAT4, OCT1, OCT3, OCTN1, OCTN2, BSEP, MRP1, MRP2, MRP3, MRP4, MRP5, MRP6, MRP7, MRP8, MRP9, MDR1, MDR1A/B, MDR2, MDR3, BCRP, ABCG5, ABCG8, and FIC-1.

C. Single Culture Biliary Excretion Assay with Marker Chemical Entity

In certain embodiments the methods of this disclosure comprise simultaneously exposing a cell culture comprising hepatocytes forming at least one bile canaliculus to a marker chemical entity and a test chemical entity and characterizing biliary excretion of the marker chemical entity in the presence of the test chemical entity in order to characterize biliary excretion of the test chemical entity. In particular, these methods allow detection of the use of a common transporter by the marker chemical entity and the test chemical entity.

For example, such methods may comprise a) providing a cell culture comprising hepatocytes forming at least one bile canaliculus; b) simultaneously contacting the cell culture with a marker chemical entity and a test chemical entity, wherein the marker chemical entity is a known substrate of at least one hepatocyte transport protein with a determined CL_(bile) and/or BEI; c) disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount of the marker chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and d) lysing the hepatocytes and detecting the amount of the marker chemical entity and/or a metabolite thereof released by the hepatocytes. In some embodiments at least one wash step is included between steps a) and b), between steps b) and c), and/or between steps c) and d).

Typically step b) is performed by diluting the marker chemical entity and test chemical entity in culture media and replacing the culture media used in step a) with the media comprising the diluted marker chemical entity and test chemical entity. After a time sufficient to allow uptake the culture media of step b) is removed from the culture. Because the hepatocytes are typically adhered to a substrate this is typically accomplished using standard tissue culture aspiration and pipetting techniques or equivalent to remove culture media and then add new media Of course, a skilled artisan will appreciate that any suitable method may be used. At this stage of the method the hepatocyte culture may be washed by one or more changes of culture media that does not comprise the marker chemical entity and test chemical entity, such as by one wash, by two washes, or by three washes. In some embodiments of the methods step b) is preceded by a step in which the culture is contacted by the test chemical entity and not the marker chemical entity to allow preloading of a transporter with the test chemical entity.

In step c) the at least one bile canaliculus is disrupted by any suitable technique known in the art. An exemplary method is by exchanging the culture media with media that is calcium free or that is calcium and magnesium free. Incubation in media that is calcium free or that is calcium and magnesium free disrupts tight junctions and causes the contents of bile canaliculi to be released into the culture media. Another exemplary method is by exchanging the culture media for media comprising an effective concentration of LatA, Incubation in media that comprising an effective concentration of LatA disrupts tight junctions and causes the contents of bile canaliculi to be released into the culture media. The detecting in step c) typically is by collecting the media following disruption of canaliculi and characterization of marker chemical entity present in the collected media. The detection may be qualitative and/or quantitative. In a preferred embodiment the detection methods comprise use of LC-MS/MS to detect the first chemical entity. In some embodiments LC-MS/MS is used to measure the amount of the marker chemical entity present in the media following disruption of the at least one bile canaliculus. In some embodiments the media comprising the material released from the canaliculi is processed to remove undesirable components using steps that may include, for example, at least one of filtration, chromatography, and centrifugation.

In step d) the remaining cells are lysed by any suitable technique known in the art. An exemplary method is by exposure to deionized water. The detecting in step d) typically is by collecting the media following lysing of the remaining cells and characterization of marker chemical entity present in the collected media. The detection may be qualitative and/or quantitative. In a preferred embodiment the detection methods comprise use of LC-MS/MS to detect the marker chemical entity. In some embodiments LC-MS/MS is used to measure the amount of the marker chemical entity present in the media following cell lysis. In some embodiments the media comprising the material released from the lysed cells is processed to remove undesirable components using steps that may include, for example, at least one of filtration, chromatography, and centrifugation.

The cell culture comprising hepatocytes forming at least one bile canaliculus may be any suitable hepatocyte culture. Typically the cell culture comprising hepatocytes forming at least one bile canaliculus is a culture configuration that does not comprise a liver slice. Exemplary cell cultures comprising hepatocytes forming at least one bile canaliculus are described in Section D: “Cultures Comprising Hepatocytes Forming a Bile Canaliculus” of this DETAILED DESCRIPTION section of the disclosure. Any Cultures Comprising Hepatocytes Forming a Bile Canaliculus may be used in the methods of this disclosure.

In some embodiments of the methods the cell culture is a hepatocyte-stromal cell coculture comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity; and the CL_(bile) and/or BEI for the marker chemical entity is lower in the presence of the test chemical entity than in the absence of the test chemical entity, indicating that biliary clearance of the test chemical entity is mediated at least in part by the at least one least one hepatocyte transport protein.

In some embodiments the methods further comprise determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity; and the CL_(bile) and/or BEI for the marker chemical entity is not lower in the presence of the test chemical entity than in the absence of the test chemical entity, indicating that biliary clearance of the test chemical entity is not mediated at least in part by the at least one least one hepatocyte transport protein.

In some embodiments of the methods the amount of the marker chemical entity and/or metabolite thereof in steps c) and/or d) is detected using LC-MS/MS. In some embodiments of the methods the amount of the marker chemical entity and/or a metabolite thereof in steps c) and d) is detected using an equivalent LC-MS/MS technique.

In some embodiments of the methods the marker chemical entity does not comprise a label. As used herein a “label” is a moiety that emits a signal that may be detected in an assay. Exemplary labels are fluorescent moieties and radioactive moieties.

In some embodiments the methods do not comprise detecting a signal from a label moiety of a chemical entity.

In some embodiments of the methods the at least one bile canaliculus is disrupted in the cell culture without lysing hepatocytes in the cell culture by incubating the cell culture in media comprising latrunculin A (LatA) and/or not comprising calcium.

In some embodiments of the methods the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes. In some embodiments the at least one hepatocyte transport protein is selected from at least one sinusoidal membrane transport protein and at least one bile membrane transport protein. In some embodiments the at least one hepatocyte transport protein is selected from NTCP, OATP1A1, OATP1A2, OATP1A4, OATPB2, OATP1B1, OATP1B3, OATP2B1, OAT2, OAT3, OAT4, OCT1, OCT3, OCTN1, OCTN2, BSEP, MRP1, MRP2, MRP3, MRP4, MRP5, MRP6, MRP7, MRP8, MRP9, MDR1, MDR1A/B, MDR2, MDR3, BCRP, ABCG5, ABCG8, and FIC-1.

D. Cultures Comprising Hepatocytes Forming a Bile Canaliculus

A bile canaliculus is a thin tube that collects bile secreted by hepatocytes. The bile canaliculi merge and form bile ductules, which eventually become the common hepatic duct. Hepatocytes are polyhedral in shape, with surfaces facing the sinusoids (called sinusoidal faces) and surfaces which contact other hepatocytes (called lateral faces). Bile canaliculi are formed by grooves on some of the lateral faces of adjacent hepatocytes. Under appropriate conditions cultured hepatocytes have the ability to form canaliculi.

The methods of this disclosure utilize in vitro cell cultures comprising hepatocytes that have formed at least one bile canaliculus. The hepatocytes may be any type of hepatocyte including without limitation primary hepatocyte, hepatocyte cell lines, and hepatocytes formed by differentiating stem cells (such as embryonic stem cells, adult stem cells, or induced pluripotent stem cells) into hepatocytes. The hepatocytes may be from any mammal. In some embodiments the hepatocytes are from a mammal selected from a human, a non-human primate (such as a cynomolgus monkey), a farm animal (such as pig, horse, cow, and sheep), a domestic mammal (such as dogs, cats, guinea pig and rabbit), and rodents (such as mice and rats). In some embodiments the hepatocyte-stromal cell cocultures comprise hepatocytes from a plurality of mammalian species.

In a preferred embodiment the hepatocytes are primary hepatocytes. Primary hepatocytes may need not be supplied in cryopreserved form. Cryopreserved human hepatocytes may be obtained from Life Technologies Corporation. Cryopreserved non-human primate hepatocytes may be obtained from Life Technologies Corporation. Cryopreserved dog hepatocytes may be obtained from IVT Bioreclemation. Cryopreserved rat hepatocytes may be obtained from Life Technologies Corporation.

In some embodiments the culture comprises hepatocytes present in a three dimensional bioprinted configuration. In some embodiments the culture comprises hepatocytes present in a spheroid configuration. In some embodiments the culture comprises hepatocytes present in a gel sandwich configuration. In some embodiments the culture comprises a capillary bed. In some embodiments the culture is made by a method that does not comprise creating a liver slice. In some embodiments the culture does not comprise a liver slice.

In some embodiments the culture is a hepatocyte-stromal cell coculture comprising hepatocytes and at least one stromal cell type disposed on the surface of a solid substrate. In some embodiments of the hepatocyte-stromal cell coculture the hepatocytes and a single stromal cell type represent at least about 95%, at least about 96%, at least about 97%, at least about 98%, at least about 99%, at least about 99.5%, at least about 99.9%, or at least about 99.99% of the cells in the coculture.

Typically the hepatocytes and stromal cells are present in the coculture at a ratio of from 1:10 to 10:1. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 2:10 to 10:2. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 2:10 to 4:10. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 4:10 to 6:10. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 6:10 to 8:10. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 8:10 to 1:1. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 1:1 to 10:8. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 10:8 to 10:6. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 10:6 to 10:4. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of from 10:4 to 10:2. In some embodiments the hepatocytes and stromal cells are present in the coculture at a ratio of about 10:1, 10:2, 10:3, 10:4, 10:5, 10:6, 10:7, 10:8, 10:9, 1:1, 9:10, 8:10, 7:10, 6:10, 5:10, 4:10, 3:10, 2:10, or 1:10.

In some embodiments the hepatocyte-stromal cell coculture comprises at least two stromal cell types. In some embodiments the hepatocyte-stromal cell coculture comprises two stromal cell types that each represent at least about 0.01%, at least about 0.1%, at least about 0.5%, at least about 1%, at least about 2%, at least about 3%, at least about 4%, at least about 5%, or at least about 10% of the cells in the coculture.

In some embodiments the stromal cell type is from the same type of mammal as the hepatocytes. In some embodiments the stromal cell type is from a different type of mammal than the hepatocytes.

In some embodiments the hepatocyte-stromal cell coculture comprises a third cell type. In some embodiments the third cell type is a stromal cell. In some embodiments the third cell type is not a stromal cell. In some embodiments the third cell type is a parenchymal cell. In some embodiments the third cell type is not a non-parenchymal cell. In some embodiments the third cell type is selected from Ito cells, endothelial cells, biliary duct cells, immune-mediating cells, and stem cells. In some embodiments, the immune-mediating cells are selected from macrophages, T cells, neutrophils, dendritic cells, mast cells, eosinophils and basophils.

In some embodiments the third cell type is a Kupffer cell. In some embodiments the Kupffer cells represent at least about 0.01%, at least about 0.1%, at least about 0.5%, at least about 1%, at least about 2%, at least about 3%, at least about 4%, at least about 5%, or at least about 10% of the cells in the coculture.

In some embodiments the stromal cell type is an endothelial cell. In some embodiments the stromal cell type is a fibroblast cell. In some embodiments the stromal cell is a primary cell. In some embodiments the stromal cell is obtained from a cell line. In some embodiments the stromal cell is a transformed cell. In some embodiments the stromal cell is differentiated in vitro from a stem cell, such as an embryonic stem cell, adult stem cell, or induced pluripotent stem cell. Numerous sources of stromal cells such as fibroblasts are known in the art and may be utilized in the hepatocyte-stromal cell cocultures. One example is the NIH 3T3-J2 cell line. (See for example US 2013/0266939 A1.)

The art teaches that some aspects of hepatocyte function in culture are improved by disposing hepatocytes and stromal cells onto a solid substrate such that the hepatocytes are attached to the substrate in a first step in a cellular island configuration. (See US 2013/0266939 A1.) Specifically, such methods rely on formation of cellular islands of hepatocytes on a substrate, the hepatocyte islands surrounded by a non-parenchymal cell type such as a stromal cell type. The hepatocyte islands are formed by first placing an extracellular matrix component or derivative onto a solid substrate in an island pattern and then allowing the hepatocytes to adhere to the extracellular matrix component or derivative. The non-parenchymal cell type is then added and allowed to “fill in” the portions of the substrate that don't contain hepatocytes. A fundamental feature of such systems is that the hepatocytes are not dispursed accross across the substrate surface.

In some embodiments the invention utilizes a hepatocyte-stromal cell coculture comprising hepatocytes distributed in a cellular island configuration such as described in US 2013/0266939 A1. However, in preferred embodiments the hepatocytes are substantially dispersed across the surface of the solid substrate.

As used herein, “dispersed across the surface” in reference to an arrangement of hepatocytes on a solid support in a hepatocyte-stromal cell coculture means that at least one of the following criteria applies to the coculture: 1) at least about 20%, at least about 30%, at least about 40%, or at least about 50% of the surface of the solid substrate is covered by at least one hepatocyte; 2) at least about 2%, at least about 5% or at least about 10% of the hepatocytes in the coculture are located on top of a stromal cell that is in contact with the solid substrate; and 3) the hepatocytes were not seeded onto the solid substrate by adding the hepatocytes to a solid substrate comprising islands of at least one extracellular matrix component to create islands of hepatocytes attached to the solid substrate. Note that a single hepatocyte may be counted as meeting criteria 1 and criteria 2.

For use in the methods of the invention the coculture comprises at least one bile canaliculus. In some embodiments the coculture comprises only a single bile canaliculus while in other embodiments the coculture comprises a plurality of canaliculi.

In preferred embodiments the metabolic function of the hepatocyte-stromal cell coculture is long enduring throughout a culture period. In some embodiments the culture period is for at least one day, at least two days, at least three days, at least five days, at least seven days, at least ten days, at least fourteen days, at least twenty-one days, or at least twenty-eight days. In some embodiments the metabolic function of the hepatocyte-stromal cell coculture is determined by measuring an activity selected from gene expression, cell function, metabolic activity, morphology, and a combination thereof, of the hepatocytes in the coculture. In some embodiments the metabolic function of the hepatocyte-stromal cell coculture is determined by measuring the level of expression and/or activity of at least one CYP450 enzyme. The level of expression and/or activity of at least one CYP450 enzyme may be measured by measuring expression of the CYP450 enzyme mRNA, by measuring expression of the CYP450 enzyme protein, or by a functional assay of CYP450 enzyme activity. In some embodiments, the metabolic activity is a CYP450 enzyme activity. In some embodiments, the CYP450 enzyme is a CYP450 enzyme selected from CYP1A2, CYP1B1, CYP2A6, CYP2B6, CYP2C, CYP2D6, CYP2E1, CYP2F1, CYP2J2, CYP3A4, CYP4A, and CYP4B.

The metabolic function of the hepatocyte-stromal cell coculture is considered long enduring if the metabolic function of the coculture endures longer in the hepatocyte-stromal cell coculture than the metabolic function of a control hepatocyte monoculture. In some embodiments the metabolic function of the coculture endures for at least seven days. In some embodiments the metabolic function of the coculture endures for at least fourteen days. In some embodiments the metabolic function of the coculture endures for at least twenty-one days. In some embodiments the metabolic function of the coculture endures for at least twenty-eight days.

In some embodiments the coculture is cultured in serum-free or essentially serum-free media. In some embodiments the coculture is cultured in media containing serum. In some embodiments the media comprises about 0.1% serum, about 0.2% serum, about 0.3% serum, about 0.4% serum, about 0.5% serum, about 0.6% serum, about 0.7% serum, about 0.8% serum, about 0.9% serum, about 1% serum, about 2% serum, about 3% serum, about 4% serum, about 5% serum, about 6% serum, about 7% serum, about 8% serum, about 9% serum, or about 10% serum. In some embodiments the media comprises at least about 0.1% serum, at least about 0.2% serum, at least about 0.3% serum, at least about 0.4% serum, at least about 0.5% serum, at least about 0.6% serum, at least about 0.7% serum, at least about 0.8% serum, at least about 0.9% serum, at least about 1% serum, at least about 2% serum, at least about 3% serum, at least about 4% serum, at least about 5% serum, at least about 6% serum, at least about 7% serum, at least about 8% serum, at least about 9% serum, or at least about 10% serum. In some embodiments the media comprises less than or equal to about 0.1% serum, less than or equal to about 0.2% serum, less than or equal to about 0.3% serum, less than or equal to about 0.4% serum, less than or equal to about 0.5% serum, less than or equal to about 0.6% serum, less than or equal to about 0.7% serum, less than or equal to about 0.8% serum, less than or equal to about 0.9% serum, less than or equal to about 1% serum, less than or equal to about 2% serum, less than or equal to about 3% serum, less than or equal to about 4% serum, less than or equal to about 5% serum, less than or equal to about 6% serum, less than or equal to about 7% serum, less than or equal to about 8% serum, less than or equal to about 9% serum, or less than or equal to about 10% serum.

E. Transporters

In some embodiments of the methods of the invention, at least one hepatocyte transporter selected from a sinusoidal membrane transporter and a canalicular transporter is inhibited. Numerous transporters are known in the art and a skilled artisan will appreciate that any known or subsequently discovered transporter may be used with the methods of the invention. Exemplary transporters include but are not limited to the sodium/bile acid cotransporter also known as the Na+-taurocholate cotransporting polypeptide (NTCP) or liver bile acid transporter (LBAT), a protein that in humans is encoded by the SLC10A1 (solute carrier family 10 member 1) gene; an organic anion-transporting polypeptide, for example one selected from OATP1A1, OATP1A2, OATP1A4, OATPB2, OATP1B1, OATP1B3, and OATP2B1; an organic anion transporter, for example one selected from OAT2, OAT3, OAT4; an organic cation transport protein, for example one selected from OCT1, OCT3, OCTN1, and OCTN2; the bile salt export pump (BSEP) protein, also known as ATP-binding cassette, sub-family B member 11 (ABCB11), encoded by the ABCB11 gene in humans; a multidrug resistance-associated protein, for example one selected from MRP1, MRP2, MRP3, MRP4, MRP5, MRP6, MRP7, MRP8, and MRP9; a P-glycoprotein, such as one selected from MDR1, MDR1A/B, MDR2, and MDR3; the ATP-binding cassette sub-family G member 2 (ABCG2), also known as BCRP, a protein that in humans is encoded by the ABCG2 gene; an ABC protein selected from ABCG5 and ABCG8; and the probable phospholipid-transporting ATPase IC (ATP8B1), also known as FIC-1, an enzyme that in humans is encoded by the ATP8B1 gene.

Numerous inhibitors of these transporter proteins are known in the art and may be used in the methods of the invention. Exemplary inhibitors of Pgp proteins include but are not limited to ritonavir, cyclosporine, verapamil, erythromycin, ketocoanzole, itraconazole, and quinidine. Exemplary inhibitors of BCRP include but are not limited to elacridar, Imatinib, and fumitremorgin C. Exemplary inhibitors of Mate 1 include but are not limited to cimetidine. Exemplary inhibitors of BSEP include but are not limited to Atorvastatin, Cerivastatin, Clofazimine, and Glyburide. Exemplary inhibitors of MRP2 include but are not limited to cyclosporine, probenecid, furosemide, and lamivudine.

EXAMPLES Example 1: Hepatocyte-Stromal Cell Cocultures

Cryopreserved human hepatocytes were removed from liquid nitrogen and thawed. After thawing, cells were resuspended in medium and cell number and cell viability was determined using trypan blue exclusion. Stromal cells were passed in a CO₂ incubator until used for experimental plating. On plating day cells were detached from the plate, washed, and resuspended in medium. Cell number and viability were determined using trypan blue exclusion.

Hepatocytes and stromal cells were seeded into collagen-coated 96-well plates at a density of 30,000 hepatocytes per well. The stromal cells were growth arrested prior to seeding. Cultures were maintained for 7 days before the start of any biliary excretion assays. Before the experiments were started, the cells were stained with CDFDA on day 7 to ensure canalicular formation.

Example 2: Excretion of Test Compound into Bile Canaliculi in Hepatocyte-Stromal Cell Cocultures

In this experiment the presence of bile canaliculi in hepatocyte-stromal cell cocultures prepared according to Example 1 was assessed. Cocultures were incubated with 5 uM 5-(and-6)-Carboxy-2′, 7′-dichloro-fluorecein diacetate (CDFDA) for 20 min. CDFDA that is taken up by hepatocytes is hydrolyzed to fluorescent 5-(and-6)-Carboxy-2′, 7′-dichloro-fluorecein (CDA) by the hepatocyte and then secreted in this fluorescent form into the canaliculus via the Mrp2 transporter. The cocultures comprised several canaliculi that are readily apparent under the microscope (data not shown). Cyclosporin A (CSA) is a known inhibitor of the Mrp2 transporter. In a subsequent experiment a coculture was incubed with CDFDA in the presence of 50 uM CSA for 20 min. No fluorescent canaliculi were visible following incubation with CDFDA in the presence of CSA (data now shown). This result demonstrates that bile canaliculi are present in the cocultures prepared according to Example 1 and demonstrates that transporter-dependent excretion of chemical entities into the canaliculi can be assessed in this system.

Example 3: Disruption of Canaliculi

Assessing excretion of a chemical entity into the bile in the hepatocyte-stromal cell coculture requires a method of distinguising between the chemical entity present in canaliculi of the coculture and chemical entity that may be present in the cytoplasm of cells in the coculture. Two methods of canalicular disruption were tested. In the first method, the cultures were exposed to a calcium free (Ca−) free buffer. The lack of calcium inhibits the ability of the cell to form tight junctions which allows bile present in the canaliculi to escape. Cells were first washed two times in HBSS buffer with Ca+. Cells were then incubated with 5 uM CDFDA in HBSS buffer without Ca− for 20 min. Cells were then washed two times in HBSS buffer without Ca−. Because accumulated CDF escaped the canaliculi after exposure to Ca− buffer no CDF staining was apparent (data not shown).

In the second method, the cultures were exposed to buffer containing latranculin A (LatA). The LatA functions to disrupt microfilament organization, a key step in tight junction formation, which allows bile present in the canaliculi to escape. Cells were first washed twice in HBSS buffer with Ca+. Cells were then incubated with 5 uM CDFDA in HBSS buffer with Ca+ and 10 uM LatA for 20 min. Cells were then washed two times in HBSS buffer with Ca+. Because accumulated CDA escaped the canaliculi after exposure to LatA containing buffer no CDA staining was apparent (data not shown).

Example 4: Biliary Excretion Assays

The data reported in Examples 2 and 3 qualitatively demonstrates the ability of the hepatocyte-stromal cell coculture system to form functional canaliculi, the ability to disrupt the canaliculi, and the ability to inhibit the function of the Mrp2 and BSEP transporter systems. This example demonstrates the capability of the system to quantitatively measure hepatobiliary excretion of taurocholate. To assess hepatobiliary transport in one coculture compartment 2 uM of taurocholate was introduced to the cellular media and allowed to incubate for 20 minutes. The media was then removed (collection #1) and stored for analysis of remaining taurocholate. The cultures were washed twice with buffer solution (collections #2 and #3) and each wash solution was stored for analysis of remaining taurocholate. The cells were then exposed to either Ca− buffer or LatA buffer for 30 minutes (collection #4) which functions to disrupt the canaliculi present in the cultures but does not lyse cells in the coculture. This releases taurocholate accumulated in the bile of the canaliculi. The cells were then exposed to deionized water (collection #5) which functions to disrupt the cellular membrane and release the compound accumulated in the cellular compartment. Because any taurocholate present in the canaliculi was already collected in collection #4, collection #5 contains any taurocholate present in the cell but not including any present in the canaliculi. The concentration of taurocholate in collection #4 (FIG. 1) and collection 5 (FIG. 2) was determined using LC-MS/MS. The experiment was run in triplicate. The underlying data shown in FIG. 1 for Lat A was 117.6 nM, 115.4 nM and 158.6 nM. The underlying data shown in FIG. 1 for Ca− was 204 nM, 150.2 nM and 158 nM. The underlying data shown in FIG. 2, collection #5, for Lat A was 199 nM, 144.4 nM and 234 nM. The underlying data shown in FIG. 2, collection #5, for Ca− numbers was 141 nM, 95.4 nM and 120.8 nM.

Samples were centrifuged at 1000×g for 10 min, and an aliquot (10 mL) of the supernatant was analyzed by LC-MS/MS. The LC-MS/MS system comprised a Shimadzu LC-10ADvp pump (Shimadzu, Columbia, Md.), HTS PAL CTC autosampler (Leap Technologies, Carboro, N.C.), and an API 4000 mass spectrometer with a Turbo Ion Spray probe (Applied Biosystems/MDS SCIEX, Ontario, Canada). The separation of compounds was achieved using a reversed phased stationary phase (Synergi Hydro, Phenomenex). The mobile phase was a gradient with 0.1% formic acid with 0.15 gm Ammonium acetate in water (A) and 0.1% formic acid with 0.15 gm Ammonium acetate in acetonitrile (B) with a flow rate of 0.5 mL/min. The initial composition of the mobile phase was 2% of B for 0.3 min, followed by a linear gradient to 100% of B over 1.3 min, and back to 2% of B in 0.2 min, and maintaining 2% B for another 0.2 min. Taurocholic acid was detected using multiple reaction monitoring (MRM) in negative ion mode. The area ratio of the analytes to the internal standard was calculated using the Analyst1 software v. 1.4.1 (Applied Biosystems). The concentrations of taurocholate in the bile and in the cell were then used to calculate the intrinsic biliary clearance (CLbile) [Equation 1] and a biliary excretion index (BEI) [Equation 2] for taurocholate in this system. The BEI for the method that used the Ca− buffer to disrupt the canaliculi was 66.9% and the BEI for the method that used the LatA buffer to disrupt the canaliculi was 40.4%. Others report similar ranges for BEI of taurocholate ranging from 41-63%. B I, Yi-an, et al., “Use of cryopreserved human hepatocytes in sandwich culture to measure hepatobiliary transport,” Drug Metab Dispos., Vol. 34, No. 9, pp. 1658-65 (2006).

$\begin{matrix} {Equations} & \; \\ {{CL}_{bile} = \frac{{Accumulation}\mspace{14mu} {in}\mspace{14mu} {Bile}}{\left\lbrack {\left( {{Incubation}\mspace{20mu} {Time}} \right) \times \left( {{Concentration}\mspace{14mu} {in}\mspace{14mu} {Media}} \right)} \right\rbrack}} & (1) \\ {{BEI} = \frac{{Accumulation}\mspace{14mu} {in}\mspace{14mu} {Bile}}{\left( {{{Accumulation}\mspace{14mu} {in}\mspace{14mu} {Cells}} + {{Accumulation}\mspace{14mu} {in}\mspace{14mu} {Bile}}} \right)}} & (2) \end{matrix}$

The effect of CSA on biliary clearance of taurocholate was then assessed using this method. The same protocol was followed except that the cocultures were exposed to the inhibitor CSA before addition of taurocholate into the cellular media. Prior to the addition of 2 uM of taurocholate, the cells were exposed to HBSS buffer with 50 uM Cyclosporine A for 20 min. Then the experiment continued as in Example 3. In this experiment Ca− buffer was used to disrupt the canaliculi. As demonstrated by the data shown in FIG. 3, incubation with CSA dramatically reduced the concentration of taurocholate accumulating in the bile.

Example 5: Uptake and Biliary Excretion in Human Hepatocyte Cocultures

Hepatocyte-stromal cell cocultures according to Example 1 were used to measure uptake rates of five compounds: taurocholic acid (taurocholate) at 2 uM, estradiol-glucuronide at 2 uM, digonxin at 2 uM, rosuvastatin at 2 uM, and pravastatin at 5 uM. The single well method of assessing biliary clearance of the invention was used.

A coculture was exposed to each tested compound in culture media at the indicated concentration for 20 minutes. The media was then removed (collection #1) and stored for analysis of remaining compound. The cultures were washed twice with buffer solution (collections #2 and #3) and each wash solution was stored for analysis of remaining taurocholate. The cells were then exposed to HEPES buffer containing latranculin at a concentration of 5 uM for 30 minutes, which functions to disrupt the canaliculi present in the cultures but does not lyse cells in the coculture. This releases taurocholate accumulated in the bile of the canaliculi. At the end of the incubation period the culture media was collected (collection #4). The cells were then exposed to deionized water which functions to disrupt the cellular membrane and release the compound accumulated in the cellular compartment (collection #5). Because any compound present in the canaliculi was already collected in collection #4, collection #5 contains any compound present in the cell but not including any present in the canaliculi. The concentration of compound in collection #4 and collection 5 was determined using LC-MS/MS as in Example 4.

The results of this analysis are presented in FIGS. 4-8. In teach figure the measured amount of compound in bile and the measured amount of compound in the cytoplasm are presented together as two parts of a single bar on the left side of the figure. The measured value for the bile is also shown as a bar on the right side of the figure. Comparing the height of the right bar (bile) to the height of the composite left bar (total of cytoplasm+bile) allows visulation of the portion of the compound that accumulated in the bile. The results for taurocholic acid (taurocholate) are shown in in FIG. 4, the results for estradiol-glucuronide are shown in FIG. 5, the results for digonxin are shown in in FIG. 6, the results for rosuvastatin are shown in FIG. 7, and the results for pravastatin are shown in FIG. 8. Equation 2 was used to calculate the BEI for each compound in this system. The data were used to calculate the Biliary Clearance (Equation 1) and BEI (Equation 2) for each tested compound. The data are presented in Table 1.

The results obtained for taurocholic acid (taurocholate), estradiol-glucuronide, digonxin, and rosuvastatin is in the range of published data that were generated using a two culture method and reported by Yi-an B I et al., “Use of Cryopreserved Human Hepatocytes in Sandwich Culture to Measure Hepatobiliary Transport,” Drug Metabolism and Disposition, Vol. 34, No. 9, pp. 1658-65 (2006), as shown in Table 1.

TABLE 1 Example 6 Data Bi et al. (2006) Taurocholic Acid Uptake Rate 38 +/− 5 11-17 (pmol/min/mg protein) Biliary Clearance 23 +/− 3  6-10 (ml/min/mg protein) Biliary Excretion Index (%) 66 +/− 9 41-72 Estradiol-Glucuronide Uptake Rate  2.0 +/− 0.1 2.2 (pmol/min/mg protein) Biliary Clearance  0.3 +/− 0.1 1.8 (ml/min/mg protein) Biliary Excretion Index (%) 40 +/− 3 37   Digoxin Uptake Rate  1.9 +/− 0.1 0.7-1.5 (pmol/min/mg protein) Biliary Clearance  0.4 +/− 0.1 0.6-1.5 (ml/min/mg protein) Biliary Excretion Index (%) 41 +/− 4 37-63 Rosuvastatin Uptake Rate 11.4 +/− 1.3 15-26 (pmol/min/mg protein) Biliary Clearance  6.0 +/− 0.7  4-12 (ml/min/mg protein) Biliary Excretion Index (%) 52 +/− 7 43-58 Pravastatin Uptake Rate  0.6 +/− 0.1 n/a (pmol/min/mg protein) Biliary Clearance  0.38 +/− 0.04 n/a (ml/min/mg protein) Biliary Excretion Index (%) 14 +/− 1 n/a

Example 6: Uptake and Biliary Excretion in Rat Hepatocyte Cocultures

Hepatocyte-stromal cell cocultures according to Example 1 were prepared using primary rat hepatocytes (Lifetech®) and used to measure uptake rates of five compounds: taurocholic acid (taurocholate), estradiol-glucuronide, digonxin, rosuvastatin, and pravastatin. The single well method of assessing biliary clearance of the invention was used.

A coculture was exposed to each tested compound in culture media at concentrations of taurocholic acid (taurocholate) at 2 uM, estradiol-glucuronide at 2 uM, digoxin at 2 uM, rosuvastatin at 2 uM, and pravastatin at 5 uM for 20 minutes. The media was then removed (collection #1) and stored for analysis of remaining compound. The cultures were washed twice with buffer solution (collections #2 and #3) and each wash solution was stored for analysis of remaining taurocholate. The cells were then exposed to HEPES buffer containing latrunculin at a concentration of 5 uM for 30 minutes, which functions to disrupt the canaliculi present in the cultures but does not lyse cells in the coculture. This releases taurocholate accumulated in the bile of the canaliculi. At the end of the incubation period the culture media was collected (collection #4). The cells were then exposed to deionized water which functions to disrupt the cellular membrane and release the compound accumulated in the cellular compartment (collection #5). Because any compound present in the canaliculi was already collected in collection #4, collection #5 contains any compound present in the cell but not including any present in the canaliculi. The concentration of compound in collection #4 and collection 5 was determined using LC-MS/MS as in Example 4. The data is presented in FIG. 9-13 using the same format as used in FIGS. 4-8.

The results for taurocholic acid (taurocholate) are shown in in FIG. 9, the results for rosuvastatin are shown in FIG. 10, the results for estradiol-glucuronide are shown in FIG. 11, the results for digonxin are show in in FIG. 12, and the results for pravastatin are shown in FIG. 13. Equation 2 was used to calculate the BEI for each compound in this system. The measured BEI of taurocholic acid (taurocholate) was 60% (FIG. 9), the measured BEI of rosuvastatin was 72% (FIG. 10), the measured BEI of estradiol-glucuronide was 40% (FIG. 11), the measured BEI of digonxin was 67% (FIG. 12), and the measured BEI of pravastatin was 58% (FIG. 13).

These data are summarized in Table 2. The values provided for in vitro CL_(bile) were calculated by converting the intrinsic Cl_(int, bile) values to ml/min/kg based on 200 mg protein/g liver and 40 g liver/kg (See Seglen, 1976). Interestingly, for the compounds where in vivo data is available the results of this example are within four fold for one compound and 2 fold in the other. This is a good in vivo to in vitro correlation for the scaled numbers and demonstrates the in vivo relevance of the methods.

TABLE 2 Example 6 Lundquist Rat In Vitro PK Example 6 (2014) Intrinsic Rat In Vitro PK Rat In Vivo PK CL_(int, biliary) Predicted In Vivo (μl/min/mg CL_(biliary) CL_(biliary) Fold Substrate protein) (ml/min/kg) (ml/min/kg) Difference Digoxin 0.31 ± 0.02  2.5 ± 0.12 0.8 ± 0.3 3.1 Rosuvastatin 3.5 ± 0.3 27.6 ± 2.1 48.0 ± 10.8 0.6 Estradiol- 2.7 ± 0.1 21.6 ± 0.4 n/a Gluc Taurocholate 8.4 ± 0.6 67.1 ± 4.8 n/a Pravastatin 0.29 ± 0.02  2.3 ± 0.14 n/a

Example 7: Transporter Inhibition Assays

Direct inhibition of efflux transporters by xenobiotics or drugs leading to acquired cholestasis and drug-induced liver injury (DILI) is a major obstacle in drug development. Understanding the potential drug-drug interaction liabilities of a compound based on in vitro testin is, therefore, desirable. In this experiment human primary hepatocyte cocultures made according to Example 1 were used in the direct measurement one culture assay format of the invention to characterize BSEP and BCRP inhibition. The probe substrates used were 2 μM taurocholic acid (BSEP efflux transporter) and 2 μM rosuvastatin (BCRP efflux transporter). Cyclosporin A is a known BSEP inhibitor and was used at 0-20 μM. Ritonavir is a known BCRP inhibitor and was used at 0-100 μM. Erythromycin Estolate is a known broad spectrum inhibitor and was used at 50 μM. In order to asses inhibition cultures were first preincubated in the indicated inhibitor for 20 min and then incubated in the presence of the substrate and inhibitor for an additional 20 min. The cultures were then washed twice to remove excess substrate and inhibitor and the protocol proceeded as in Example 5. The data for BSEP inhibition by cyclosporin A are shown in FIG. 14. Cyclosporin A inhibited BSEP mediated transport of taurocholate with an IC₅₀ of 0.46 μM. The data for BCRP inhibition by ritonavir are shown in FIG. 15. Ritonavir inhibited BCRP mediated transport of ritonavir with an IC₅₀ of 0.50 μM. Inhibition by erythromycin estolate was performed in the same way except that substrates taurocholate and ritonavir were added together. As shown in FIG. 16, erythromycin estolate completely inhibited BSEP mediated transport of taurocholate and significantly inhibited BCRP mediated transport of ritonavir. Taken together, these data demonstrate the utility of the the direct measurement one culture assay format of the invention for characterizing inhibition of efflux transporters by xenobiotics or drugs. [EN: Please add any additional conclusions or clarifications.]

Example 8: Reproducibility

In contrast to prior art methods, the methods of this invention comprise direct measurement of biliary excretion of a chemical entity in a one culture assay format. The accuracy and reproducibility of this assay format was demonstrated by performing three independent assays using human hepatocyte stromal cell coculture according to Example 1, for each of taurocholate and pravastatin. The data for taurocholic acid are shown in Table 3 and FIG. 17. The data for pravastatin are shown in Table 4 and FIG. 18. A statistical analysis presented in Table 5 indicates that there is no statistically-significant variation (P<0.05) in the results of the replicate assay results for each compound.

TABLE 3 Taurocholic Acid Bile Cell Mean SD Mean SD Exp. 1 541.90 7.22 273.08 86.93 Exp. 2 556.08 22.47 423.21 25.08 Exp. 3 543.31 50.15 151.91 13.37

TABLE 4 Pravastatin Bile Cell Mean SD Mean SD Exp. 1 1.69 0.27 10.58 0.89 Exp. 2 4.38 0.61 16.99 8.31 Exp. 3 2.19 0.09 7.82 3.01

TABLE 5 Statistical Analysis Substrate Data Substrate Location P value Comparison Results Taurocholic Bile 0.62 exp1 vs exp2 no significant Acid difference Bile 0.98 exp1 vs exp3 no significant difference Bile 0.63 exp2 vs exp3 no significant difference Taurocholic Cell 0.31 exp1 vs exp2 no significant Acid difference Cell 0.26 exp1 vs exp3 no significant difference Cell 0.06 exp2 vs exp3 no significant difference Pravastatin Bile 0.06 exp1 vs exp2 no significant difference Bile 0.30 exp1 vs exp3 no significant difference Bile 0.14 exp2 vs exp3 no significant difference Pravastatin Cell 0.50 exp1 vs exp2 no significant difference Cell 0.50 exp1 vs exp3 no significant difference Cell 0.25 exp2 vs exp3 no significant difference 

1. An in vitro method of characterizing biliary excretion of a chemical entity, comprising: a) providing cell culture comprising hepatocytes forming at least one bile canaliculus; b) contacting the cell culture with a first chemical entity for a time sufficient to allow uptake of the chemical entity by hepatocytes in the culture; c) disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and d) lysing the hepatocytes and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes.
 2. The method of claim 1, wherein the cell culture is a hepatocyte-stromal cell coculture comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.
 3. The method of claim 1, wherein the amount of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c) is higher than the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes in step d).
 4. The method of claim 1, wherein the amount of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c) is lower than the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes in step d).
 5. The method of claim 1, wherein the amount of the first chemical entity and/or a metabolite thereof in steps c) and/or d) is detected using LC-MS/MS.
 6. The method of claim 1, wherein the first chemical entity does not comprise a label.
 7. The method of claim 1, wherein the at least one bile canaliculus is disrupted without lysing hepatocytes in the culture by incubating the culture in media comprising latrunculin A (LatA) and/or not comprising calcium.
 8. The method of claim 1, further comprising determining the intrinsic biliary clearance (CL_(bile)) and/or the biliary excretion index (BEI) for the first chemical entity in the cell culture.
 9. The method of claim 8, further comprising comparing the CL_(bile) and/or BEI of the first chemical entity to the CL_(bile) and/or BEI of a control chemical entity and characterizing the biliary excretion of the first chemical entity based on the comparison.
 10. The method of claim 1, wherein the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes.
 11. The method of claim 1, further comprising contacting the cell culture with a second chemical entity in step b).
 12. The method of claim 11, further comprising detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in step c).
 13. The method of claim 12, further comprising detecting the amount of the second chemical entity and/or a metabolite thereof released by the hepatocytes in step d).
 14. An in vitro method of characterizing biliary excretion of a chemical entity, comprising: a) providing a first cell culture comprising hepatocytes forming at least one bile canaliculus, wherein the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes of the first cell culture; b) contacting the first cell culture with a first chemical entity; c) disrupting the at least one bile canaliculus in the first cell culture without lysing the hepatocytes in the first cell culture and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; d) lysing the hepatocytes in the first cell culture and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes; e) providing a second cell culture comprising hepatocytes forming at least one bile canaliculus, wherein the activity of the at least one hepatocyte transport protein is not inhibited in the hepatocytes of the second cell culture; f) contacting the second cell culture with the first chemical entity; g) disrupting the at least one bile canaliculus in the second cell culture without lysing the hepatocytes in the second cell culture and detecting the amount (if any) of the first chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and h) lysing the hepatocytes in the second cell culture and detecting the amount of the first chemical entity and/or a metabolite thereof released by the hepatocytes.
 15. The method of claim 14, wherein the first and second cell cultures are hepatocyte-stromal cell cocultures comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.
 16. The method of claim 14, further comprising determining the CL_(bile) and/or BEI for the first chemical entity in the first cell culture and determining the CL_(bile) and/or BEI for the first chemical entity in the second cell culture.
 17. The method of claim 16, wherein the CL_(bile) and/or BEI for the first chemical entity is lower in the first cell culture than in the second cell culture, indicating that biliary clearance of the first chemical entity is mediated at least on part by the at least one hepatocyte transport protein.
 18. The method of claim 16, wherein the CL_(bile) and/or BEI for the first chemical entity is not lower in the first cell culture than in the second cell culture, indicating that biliary clearance of the first chemical entity is not mediated at least on part by the at least one hepatocyte transport protein.
 19. The method of claim 14, wherein the amount of the first chemical entity and/or a metabolite thereof in steps c) and/or d) and/or e) and/or h) is detected using LC-MS/MS.
 20. The method of claim 14, wherein the first chemical entity and/or a metabolite thereof in steps b) and/or f) does not comprise a label.
 21. The method of claim 14, wherein the at least one bile canaliculus is disrupted in the first and second cell cultures without lysing hepatocytes in the cell cultures by incubating the cell cultures in media comprising latrunculin A (LatA) and/or not comprising calcium.
 22. The method of claim 14, further comprising contacting the first and/or second cell cultures with a second chemical entity in steps b) and/or f).
 23. The method of claim 22, further comprising detecting the amount of the second chemical entity and/or a metabolite thereof released by the at least one bile canaliculus in steps c) and/or g).
 24. The method of claim 23, further comprising detecting the amount of the second chemical entity and/or a metabolite thereof released by the hepatocytes in steps d) and/or h).
 25. An in vitro method of characterizing biliary excretion of a test chemical entity, comprising: a) providing a cell culture comprising hepatocytes forming at least one bile canaliculus; b) simultaneously contacting the cell culture with a marker chemical entity and a test chemical entity, wherein the marker chemical entity is a known substrate of at least one hepatocyte transport protein with a determined CL_(bile) and/or BEI; c) disrupting the at least one bile canaliculus without lysing the hepatocytes and detecting the amount of the marker chemical entity and/or a metabolite thereof released by the at least one bile canaliculus; and d) lysing the hepatocytes and detecting the amount of the marker chemical entity and/or a metabolite thereof released by the hepatocytes.
 26. The method of claim 25, wherein the cell culture is a hepatocyte-stromal cell coculture comprising hepatocytes and stromal cells disposed on a surface of a solid substrate.
 27. The method of claim 25, further comprising determining the CL_(bile) and/or BEI for the marker chemical entity in the hepatocyte-stromal cell coculture in the presence of the test chemical entity.
 28. The method of claim 27, wherein the CL_(bile) and/or BEI for the marker chemical entity is lower in the presence of the test chemical entity than in the absence of the test chemical entity, indicating that biliary clearance of the test chemical entity is mediated at least in part by the at least one least one hepatocyte transport protein.
 29. The method of claim 27, wherein the CL_(bile) and/or BEI for the marker chemical entity is not lower in the presence of the test chemical entity than in the absence of the test chemical entity, indicating that biliary clearance of the test chemical entity is not mediated at least in part by the at least one least one hepatocyte transport protein.
 30. The method of claim 25, wherein the amount of the marker chemical entity and/or metabolite thereof in steps c) and/or d) is detected using LC-MS/MS.
 31. The method of claim 25, wherein the at least one bile canaliculus is disrupted in the cell culture without lysing hepatocytes in the cell culture by incubating the cell culture in media comprising latrunculin A (LatA) and/or not comprising calcium.
 32. The method of claim 25, wherein the activity of at least one hepatocyte transport protein is inhibited in the hepatocytes of the cell culture. 